Solar-pumped active device

ABSTRACT

The present invention provides a solar-pumped active device which utilizes a holographic antenna grating on a solar energy silicon substrate to select specific diffracted wavelength and couple pump wavelength in an approximately vertical way and converge the pump wavelength to excite an optical gain medium so that an optical amplifier or a laser can be obtained. The present invention requires no big size and is flexible over the surface shape and is suitable for free space optical communications on the ground and satellite optical communications. It means that the holographic antenna grating can be applied on the top floor of a building or on the glass surface of an outer wall. If it is applied to a satellite, the present invention can be deposited on a solar energy cell substrate to form a high optical amplification so that not only the electricity required in satellite optical communications can be reduced, but also a high-speed and large capacity of data can be transferred between satellites.

FIELD OF THE INVENTION

The present invention relates to a solar-pumped active device. Moreparticularly, the present invention relates to an active device using aholographic antenna grating on a solar energy silicon substrate tocouple the required specific pump wavelength in sun light in anapproximately vertical direction to generate a laser. Or, in the activedevice, the spared pump wavelength propagated through the solar energysilicon substrate is diffracted into an optical gain medium again to beamplified by using a reflection layer.

DESCRIPTION OF THE RELATED ART

The erbium-doped (Er-doped) fiber amplifier (EDFA) generally excites a10-meter Er-doped fiber with a laser of 980 nm (nanometer) wavelength toproduce a light amplification gain of 20 dB (decibel) to 30 dB during1530 nm to 1560 nm. Nevertheless, about one ampere current is constantlyconsumed on driving the semiconductor laser and the cooling chip fortemperature control, not to mention that a pump wavelength of 1480 nmwould consume more electricity. This would bottlenecks the applicationsof the optical communications in some special environments, such as thesatellite, the mountain, the desert, the South Pole, or the North Pole,where electricity is hard to obtain. To generate electricity by solarenergy is now widely welcomed and assiduously developed in manycountries due to its harmlessness to the environment and resource of theearth. Similar effort has been made on converging sunlight to exciteoptical gain medium for producing a laser having high energy of tens ofwatts, which was made successful in the laboratory decades ago and isone of the subjects for the scientists to study continuously. However,large-scale focusing lens are used in most of the conventional methodsto collect sufficient pump wavelength needed in sunlight for obtaininglarger gain. With such a structure, solar-pumped laser or opticalamplifier are only suitable in use of studies inside laboratories by fewscientists. Therefore, this structure is not generally suitable forcommercial products, not to mention it is a too big device to beinstalled on an artificial satellite or in an international spacestation. Yet, in order to meet the demand on the transmission of greatamount of data or images in a short time for meteorological or militarysatellites, the satellite optical communication is one of thesignificant items assiduously developed nowadays by those countries withadvanced technologies. The wireless optical communication is of no doubtthe best choice for high speed data transmission between a satellite andanother satellite or even between a satellite and a ground station. Inaddition, the high directionality of a laser also provides thecommunication with high confidentiality. And, so, the satellite opticalcommunication is also one of the significant items being developed bythe defense authorities of all countries. Therefore, in order to realizethe idea of wireless optical communications for the artificialsatellites, a solar power amplifier in a small size but with highconvert efficiency is becoming one of the necessary and importantdevices.

Conventionally, a laser with high gain and high output power (up to 18watts) can be obtained by pumping the sunlight. However, the sunlight isalmost always focused by a large-scale parabolic lens or by usingfocusing methods of non-imaging optics, which makes the structure of thewhole laboratory seem quite huge and diminish the practicability.Furthermore, because almost all of the sunlight is focused onto theoptical gain medium, the optical gain medium has to be cooled down bycooling water simultaneously to prevent the lens from over-heating. Asillustrated above, in the future, the main factor for whether the solarpower optical amplifier and the laser would be successfully practicablelies on the use of a focusing method which is characterized in selectivewavelengths and the small size of the device.

In the prior art, a holographic grating is added into the structure ofthe optical waveguide so that the transmission energy in the opticalwaveguide can be coupled in an almost vertical direction to beirradiated and to form a focusing effect like a Fresnel lens. And,according to the principle of the reversibility of the optical path, ifa parallel beam is vertically impinged to the optical waveguide grating,the beam will be coupled into the optical waveguide and will be focusedat the focal point, which is known as a holographic antenna grating. Themaximum diffraction efficiency of such a grating for a specificwavelength is about 40 percent. And a reflection layer can be simplydeposited under the grating to reflect the spared pump light to thediffraction grating for increasing its diffraction efficiency. However,the grating is only used to couple the signal light in the opticalwaveguide to be irradiated, or to couple external signal light to theoptical waveguide to be transferred, wherein no collector of alarge-facet holographic antenna grating is proposed to collect specificwavelength from sunlight for being coupled to an optical gain medium toform a laser.

Now, the holographic antenna grating is used to couple the external pumplight to be transferred in an almost vertical direction into the opticalwaveguide which comprises an optical gain medium at the bottom; and soan optical amplifier is obtained. Therein, however, no fabrication of alarge-facet coupling device for specific sunlight wavelength isproposed, neither is proposed a fabrication of a complete round-shapedholographic grating which can converge pump wavelength into the gratingcenter to collect mass energy to excite optical gain medium forobtaining a laser and for optical amplification. Moreover, the way forobtaining the optical signal gain is by the effect of the evanescentfield, whose excite effect is not as effective as the present inventionowing to that the evanescent field can directly couple the pump lightinto a high-doped Er waveguide to obtain a strong overlapping among thesignal light, the pump light and the optical gain medium.

SUMMARY OF THE INVENTION

Therefore, the main purpose of the present invention is to couplerequired pump wavelength in sunlight in an almost vertical direction bya holographic antenna grating, wherein the wavelength is transferredhorizontally and converged at the optical gain medium to be excited bythe pump wavelength for obtaining a laser.

Another purpose of the present invention is to substantially improve thevertical-oriented diffraction efficiency; and, by using a reflectionlayer, the spared pump wavelength propagated through the solar energysilicon substrate can be diffracted into an optical gain medium again tobe amplified and so to improve the diffraction efficiency.

A further purpose of the present invention is to provide a solar energypump light amplifier which needs no electricity and is suitable forspecial environments, such as the artificial satellite, theinternational space station, the adventure station for externalcelestial bodies, the international long-distance air route airplanes,the mountains, the deserts, the South Pole and the North Pole, etc. Ifthe present invention is equipped with a backup solar cell, the presentinvention can be used as a signal amplification device in opticalcommunications to save energy in usage. But, while the present inventionis used on the ground, it is better to be used in the areas with dryclimate, such as the continental areas or the desert areas, though thedust storm seasons are exceptions; and it is suitable to be deposited onthe top of an enterprise building.

The last purpose of the present invention is to meet the demand onelectricity for the optical amplifiers in the optical communications.

To achieve the above purposes, the present invention is a solar-pumpedactive device which comprises a solar energy silicon substrate with aholographic antenna grating, wherein an optical waveguide is at thecenter of the grating. By the grating, the required pump wavelength insunlight is coupled in an almost vertical direction and then istransferred horizontally and converged at the optical gain medium to beexcited by the pump wavelength for substantially improving thediffraction efficiency. An optical gain medium is at the center of theoptical waveguide. A reflection layer is on the solar energy siliconsubstrate, by which the spared pump wavelength propagated through thesolar energy silicon substrate is diffracted into an optical gain mediumagain for improving the total diffraction efficiency. The presentinvention meets the demand on electricity for the optical amplifiers inthe optical communications and is suitable for special environments,such as the artificial satellite, the international space station, theadventure station for external celestial bodies, the internationallong-distance air route airplanes, the mountains, the deserts, the SouthPole, the North Pole, etc. If a backup solar cell is equipped with thepresent invention in usage, it can be used as a signal amplificationdevice in optical communications to save energy. But, while the presentinvention is in use on the ground, it is better to be used in the areaswith dry climate, such as the continental areas or the desert areas,though the dust storm seasons are exceptions. And the present inventionis suitable to be deposited on the top of an enterprise building.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be better understood from the followingdetailed description of preferred embodiments of the invention, taken inconjunction with the accompanying drawings, in which:

FIG. 1 is a vertical view of the operation principle of the opticalamplifier according to the present invention;

FIG. 2 is a side view of the optical amplifier according to the presentinvention;

FIG. 3 is a cross-section view of the optical amplifier according to thepresent invention;

FIG. 4 is a vertical view of the operation principle of the laseraccording to the present invention;

FIG. 5 is a view of the serial connection of the optical amplifiersaccording to the present invention;

FIG. 6 is a view of the serial connection of the lasers according to thepresent invention;

FIG. 7 is a spectrum view showing the absorption of the erbium-dopedglass according to the present invention;

FIG. 8 is a spectrum view of the 980 nm-laser diode according to thepresent invention, wherein ‘nm’ stands for ‘nanometer’;

FIG. 9 is a spectrum view showing the gain obtained from theerbium-doped glass waveguide impinged by a halogen light bulb with 250 W(watt) according to the present invention;

FIG. 10 is a spectrum view showing the gain obtained from theerbium-doped glass waveguide impinged by a 980 nm laser with 280 mW(milli-watt) according to the present invention;

FIG. 11 is a spectrum view showing the gain obtained from theerbium-doped glass waveguide where the sunlight is focused by a Fresnellens of a square of 30 cm×30 cm according to the present invention,wherein ‘cm’ stands for ‘centimeter’;

FIG. 12 is a view showing the strength of the sunlight where the currentof the 980 nm laser is adjusted to simulate the status of FIG. 11according to the present invention; and

FIG. 13 is a view showing the spectrum of the solar radiation from 10 nm(nanometer) to 100,000 nm which is measured by US Naval ResearchLaboratory.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The following descriptions of the preferred embodiments are provided tounderstand the features and the structures of the present invention.

Please refer to FIG. 1 through FIG. 3, which are a vertical view of theoperation principle, a side view, and a cross-sectional view, of theoptical amplifier according to the present invention. As shown in thefigures, the present invention is a solar-pumped active device whichcomprises a solar energy silicon substrate 1, an optical diffractionelement 21, a first optical reflection element 22, an optical waveguide3, an anti-reflection film 11, an optical gain medium 4, an input port61, an output port 62 and a reflection layer 5.

Therein, on the solar energy silicon substrate 1 are a reflection layer5 with a waveguide layer 12 which comprises an optical diffractionelement 21; an optical waveguide 3; an optical gain medium 4; and ananti-reflection film 11. The required wavelength is coupled by theoptical diffraction element 21 of the waveguide layer 12 and the firstoptical reflection element 22 of the optical waveguide 3; and then it isconverged to the optical gain medium 4 so that the signal launched intothe input port 61 is then amplified and transmitted through the outputport 62. Accordingly, an amplifier is obtained.

The solar energy silicon substrate 1 can further be a substrate coveredwith a silicon dioxide waveguide layer 12 having a thickness of aroundseveral optical wavelengths. An optical diffraction element 21 is on thesolar energy silicon substrate 1, which element can be a holographicantenna grating or a photonic crystal in a surface-relief type or anindex-modulation type made into a large facet for collecting sufficientsunlight. An optical waveguide 3 is at the center of the presentinvention. An optical gain medium 4 is at the center of the opticalwaveguide 3, which medium can be a highly-doped erbium (Er) glass, anytterbium-doped (Yb-doped) glass, an Er/Yb co-doped glass, or a glass ofa rare earth element. The Er-doped glass is radiation-hardened toprevent from the solarization effect. A first optical reflection element22 is on both sides of the optical gain medium 4, which element can be areflection grating, a Bragg grating, or a reflection grating for pumpwavelength. A reflection layer 5 and an anti-reflection film 11 arecovered on the solar energy silicon substrate 1 to improve the lightabsorption efficiency. The required pump wavelength in sunlight iscoupled in an almost vertical direction by the optical diffractionelement 21, which wavelength is transferred horizontally and thenconverged at the optical gain medium to be excited by the pumpwavelength. The spared pump wavelength propagated through the solarenergy silicon substrate 1 is diffracted into the optical gain medium 4again by the reflection layer 5 so that the signal launched into theinput port 61 is then amplified and transmitted through the output port.Accordingly, an amplifier is obtained.

Please refer to FIG. 4, which is a vertical view of the operationprinciple of the laser according to the present invention. Here, thepresent invention at least comprises a solar energy silicon substrate 1,an optical diffraction element 21, a first optical reflection element22, a second optical reflection element 23, an optical gain medium 4, anoutput port 72, an anti-reflection film 5 and a reflection layer 11.

Therein, the solar energy silicon substrate 1 is covered with areflection layer 5 and a silicon dioxide layer 12, and on the substrate1 are an optical diffraction element 21, an optical gain medium 4, andan anti-reflection film 11. The required pump wavelength is coupled intothe optical waveguide 3 by the optical diffraction element 21 and isconfined to propagate along the optical waveguide 3 back and forth bythe first optical reflection element 22; and then, it repeatedly excitesthe optical gain medium 4 to obtain a laser in coordination with thesecond optical reflection element 23; and then, it is transmittedthrough the output port 72.

The solar energy silicon substrate 1 can further be a substrate coveredwith a silicon dioxide waveguide layer 12 having a thickness of aboutseveral microns. An optical diffraction element 21 is on the solarenergy silicon substrate 1, which element can be a holographic antennagrating in a surface-relief type or an index-modulation type or aphotonic crystal made into a large facet for collecting sufficientsunlight. An optical waveguide 3 is at the center of the presentinvention. An optical gain medium 4 is at the center of the opticalwaveguide 3, which medium can be a highly-doped Er glass, an Yb-dopedglass, an Er/Yb co-doped glass, or a glass of a rare earth element. TheEr-doped glass is radiation-hardened to prevent from solarizationeffect. A first optical reflection element 22 is on both sides of theoptical gain medium 4, which element can be a reflection grating, aBragg grating, or a reflection grating for pump wavelength. A reflectionlayer 5 and an anti-reflection film 11 are on the solar energy siliconsubstrate 1 to improve light absorption efficiency. The required pumpwavelength in sunlight is coupled in an almost vertical direction by theoptical diffraction element 21, which wavelength is transferredhorizontally and then is converged at the optical gain medium 4 to beexcited by the pump wavelength. The spared pump wavelength propagatedthrough the silicon dioxide waveguide layer 12 is diffracted into theoptical gain medium 4 again by the reflection layer 5. And, bycoordinating with the second optical reflection element 23 on both sidesof the optical gain medium 4, a laser is obtained and is outputted bythe output port 72. The second optical reflection element 23 can be areflection grating for lasing wavelength.

Therein, the optical diffraction element 21 can further be substitutedwith a photonic crystal to achieve the effect of the present invention.The vertical diffraction efficiency of the photonic crystal is higher sothat the holographic antenna grating of the present invention can besubstituted with a photonic crystal; yet, the reflection grating forpump wavelength and the reflection grating for lasing wavelength arereflecting the specific wavelength by the photonic band gap of thephotonic crystal, wherein the operation is not the same as thereflection done by the photonic crystal that substitutes the holographicantenna grating.

And, further by the characteristic of the dispersion of the optical gainmedium 4 and the different characteristics of the silicon dioxide layernear by, the present invention can obtain a laser or an amplifier for Sband or another band of light. If the optical gain medium 4 is Er-dopedor Er/Yb-doped and the optical gain medium 4 is boron-doped and theholographic silicon dioxide grating layer is fluorine-doped, a laser andan amplifier for S band of light can be made according to thecharacteristic of the dispersion of the material or according to thecharacteristic of the higher material dispersion slope of the opticalgain medium 4 than that of the silicon dioxide layer 12, no matter whatmaterial is doped into the optical gain medium 4 or the silicon dioxidelayer 12. Accordingly, a laser and an amplifier for C band of light withshorter wavelength are obtained. Besides, if the optical gain medium 4is Er-doped or Er/Yb-doped, it can be further doped with aluminum; and,if doped with a rare earth element, further boron-doped orgermanium-doped. And, the silicon dioxide can further be substituted bya polymer. Because no electricity is in need in the present invention,the substrate 1 of the present invention can be made of another metal ora polymer or a dielectric material. The shape of the holographic antennagrating is not limited to be a circle; it can further be an ellipse orany other geometric shape. The host material for the optical gain medium4 can be a phosphate glass, a fluorophosphates glass, a silicate glass,or a borate glass.

The present invention can be applied in many environments, such as theoptical communications between satellites, the optical fibercommunications, the wireless optical communications, etc., and can solvethe problem of the electricity needed by the optical amplifier in theoptical communications nowadays, wherein a solar-pumped opticalamplifier required no electricity is obtained that can be used inspecial environments, such as the artificial satellites, theinternational space stations, the adventuring stations of externalcelestial bodies, the international long-distance air route airplanes,the mountains, the deserts, the South Pole and the North Pole. If thepresent invention is equipped with a backup solar cell in usage, it canbe used as a signal amplification device in the optical communicationsto saves energy. But, while the present invention is used on the ground,it is better to be used in areas of dry climate, such as the continentalareas or the desert areas, wherein dust storm seasons are exceptions;and it is suitable to be deposited on the top of an enterprise building.In short, the present invention is suitable for all applications ofsolar energy silicon substrate 1 (solar energy cells).

The holographic antenna grating which is capable of selecting wavelengthcan couple the almost vertically impinged pump wavelength in thespectrum of sunlight to become a pump wavelength propagating in ahorizontal direction. The benefit is that, by using the waveguide layer12 on the solar energy silicon substrate 1, the 980 nm (nanometer) or1480 nm pump wavelength in sunlight can be coupled vertically into thewaveguide layer 11. And then the pump wavelength is converged to thecenter of the holographic antenna grating 21 to enter into the Er-dopedglass of the optical waveguide 3, so that the erbium ions are excited bya pump wavelength power to obtain the effect of optical amplification.By further coordinating with a reflection grating for lasing wavelength,a laser can be obtained. Therein, only the wavelength in the holographicantenna grating 2 which is diffracted around 980 nm or 1480 nm entersinto the optical waveguide 3; and, the main light absorption band (550nm to 750 nm) of the solar energy silicon substrate 1 (solar energycell) for generating electricity will not be affected. Therefore, theadvantage of the present invention is that the optical communication canbe achieved by simply applying a waveguide layer 11 on the solar energysilicon substrate 1 which formerly has a large facet and by fabricatinga holographic antenna grating 2 of large facet thereon, while there isno influence on generating electricity by the solar energy siliconsubstrate 1 (solar energy cell). However, a critical defect of theholographic antenna grating 2 is that, theoretically, its maximumdiffraction efficiency is only 40 percent. In another word, only 40percent of 980 nm wavelength in sunlight can be coupled and betransferred horizontally to enter into the optical waveguide 3 at thecenter, and the other 60 percent of wavelength will propagate to thesolar energy silicon substrate 1 (solar energy cell) at the bottom.According to the experimental results of the present invention, thediffraction efficiency is estimated to be around 30 percent, but it canstill form a pump energy greater than 200 mW (milli-watt) on asquare-shaped diffraction plate with a facet of 30 cm×30 cm. Concerningthe diffraction efficiency, by simply adding a 980 nm refection layer 5under the holographic antenna grating 2, The spared pump wavelengthpropagate through the silicon dioxide waveguide layer 12 can bereflected back to the holographic antenna grating 2, followed bytransferring to the waveguide layer 12 and propagating into the opticalgain medium 4 to obtain an amplifier. Thereby, the diffractionefficiency of the holographic antenna grating 2 can be improvedindirectly.

Please refer to FIG. 5, which is a view of a serial connection of theoptical amplifiers according to the present invention. Therein, anamplifier can be obtained by serializing the amplifiers as connectingthe output of a solar-pumped active device with the input of anothersolar-pumped active device.

Please refer to FIG. 6, which is a view of a serial connection of thelaser according to the present invention. Therein, a laser can beobtained by serializing the lasers as connecting the output of asolar-pumped active device with the input of another solar-pumped activedevice for achieving the effect of.

Please refer to FIG. 7 and FIG. 8, which are spectrum views showing theabsorption of the Er-doped glass and the 980 nm laser diode according tothe present invention. As shown in the figures, a spectrum of solarradiation measured by US Naval Research Laboratory is used to obtain asimple estimation:

1. According to FIG. 13, measured by US Naval Research Laboratory, thetotal power of sunlight on the ground in one square meter is 1366 W/m²,while ‘W’ stands for ‘watt’ and ‘m’ stands for ‘meter’; the energyaround exact 980 nm is 887.5 mW/nmZm². The pump wavelength of thesunlight that can excite the optical gain medium 4 is only thewavelength of from 970 nm to 980 nm. (As shown in FIG. 7.) In fact, thewavelength of from 965 nm to 985 nm can be coupled into the waveguidelayer 12 in an approximately vertical direction. On considering theabove situations, the effective energy of pump wavelength obtained fromthe sunlight is 887.5 mW/nmZm²×(985−975)=8875 mW/m²=8875×10−4 mW/cm².

2. By using a square-shaped holographic antenna grating 2 with a facetof 30 cm×30 cm, the total power of the pump wavelength absorbed from thesunlight is 8875×10−4 mW/cm²×30 cm×30 cm=789.75 mW.

3. According to the theory of the holographic antenna grating 2, themaximum diffraction rate is 40%. If the diffraction rate obtained isaround 30%, the total power of the pump wavelength received is 789.75mW×0.3=236.925 mW. In another word, by using a holographic antennagrating 2 with a facet of 30 cm×30 cm, more than 200 mW of 980 nm pumppower is obtained, which is the power around exact 980 nm. In addition,the facet of the solar energy cell plate on the satellite has a size ofseveral square meters. Therefore, the practicability of the presentinvention is for sure.

The power for the commercial 980 nm pump laser is usually expressed withthe measurement obtained by an integrating sphere and a power-meter.Therefore, generally, a 980 nm laser with 200 mW does not mean thatthere is really a power of 200 mW existed around 980 nm; rather, itmeans an integral of all the spectrum energy. But now, by using a 280 mWof high efficiency 980 nm pump laser, the measurement obtained by thepower-meter is really almost 280 mW. However, by using a spectrumanalyzer, much power outside of 980 nm can be found. (As shown in FIG.8.) Therefore, the method used in the present invention for measuringthe power of pump wavelength from sunlight is much severer than thatwhich is generally used.

Please refer to FIG. 9 and FIG. 10, which are spectrum views showing thespectra of Amplified Spontaneous Emission (ASE) obtained from theerbium-doped glass waveguide impinged by a 250 W (watt) halogen bulb andby a 980 nm laser with 280 mW, according to the present invention. Asshown in the figures, the following is a comparison between the methodsof exciting the optical gain medium 4 (i.e. Er-doped glass) on its sidewith a 250 W halogen bulb (as shown in FIG. 9) and with a 280 mW of 980nm pump laser (as shown in FIG. 10):

4. By exciting a highly Er-doped glass of a dimension of 20 mm(millimeter) in length and 17 mm in width and 5 mm in height with a 250W halogen bulb, a spectrum of an ASE from the optical Er-doped fiberamplifier is obtained, as shown in FIG. 9.

5. By using a 280 mW of 980 nm pump laser, a spectrum of an ASE from theoptical Er-doped fiber amplifier is obtained, as shown in FIG. 10.

Comparing FIG. 9 with FIG. 10, the 1.53 mm (micrometer) wavelength powercan reach the similar level in both figures. In another word, thecapacity of a 250 W halogen bulb for exciting the optical gain medium 4(i.e. Er-doped glass) on its side is similar to that of a 980 nmsemiconductor laser of 280 mW. And, the ASE power of the Er-dopedamplifier seems very weak. One of the reason is that the ASE power ofthe optical Er-doped fiber amplifier outputted from the optical gainmedium 4 (i.e. Er-doped glass) is not focused into the spectrumanalyzer. And, another reason is that the pump wavelength can not fullyexcite such a big optical gain medium 4 (i.e. Er-doped glass). Yet thecomparative result will not be influenced under such a condition. Thegain of 1.53 mm wavelength in FIG. 9 seems smaller than that of FIG. 10,which is caused by that more white light is directed in by the halogenbulb to enter into the spectrum analyzer and so the noise level becomeshigher. Here, the only concern is on how much power can be generated bythe ASE of the Er-doped fiber amplifier, which is related to the pumpingability of the light. If the other wavelengths from the halogen bulb arefiltered off, the gain obtained in FIG. 9 can be as much as that in theFIG. 10. In the other hand, the solar energy for one square meter can beassumed as about 1.36 kW (kilowatt). Even though the diffractionefficiency of the holographic antenna grating 2 is only around 30%, atotal power of about 450 W can still be obtained, wherein the power isstill more than that which is generated by the 250 W halogen bulb.Therefore, by using a holographic diffraction plate with a facet of 50cm×50 cm only, efficiency like that of a 980 nm pump laser of 280 mW canbe achieved successfully.

Please refer to FIG. 11 and FIG. 12, which are a spectrum view showingthe ASE obtained from the optical gain medium where the sunlight isfocused to a Fresnel lens of a square of 30 cm×30 cm and a view showingthe strength of the sunlight simulating FIG. 11 by adjusting the currentof the 980 nm laser, according to the present invention.

The following is the comparison made between the results of exciting theoptical gain medium 4 (i.e. Er-doped glass) by focusing the sunlight andby a 980 nm pump laser of 100 mW:

6. At noon in a sunny day, in a temperature of 30 Celsius degrees, byusing a holographic Fresnel-lens focusing plate of acrylic material witha facet of 30 cm′30 cm, the sunlight is focused onto the optical gainmedium 4 (i.e. Er-doped glass) on its side. By using the spectrumanalyzer to measure the amplification effect of the optical gain medium4, the optical ASE spectrum is obtained as illustrated in FIG. 11,wherein the stimulated emission and the spontaneous emission aremeasured directly without using the focusing lens. The power of 1.54 mmwavelength can reach about −40 dBm, wherein the attenuation around 1.4mm is caused by the absorption of the band gap of the acrylic material.

7. Concerning the 980 nm pump laser under a 206 milliampere current, thepower is measured as 100 mW by a power-meter. Under the sameexperimental conditions, by using the power to excite on the sides, theoptical gain medium 4 (i.e. Er-doped glass) is excited to obtain ASEspectrum as illustrated in FIG. 12, wherein the ASE power obtained at1.53 mm is about −42 dBm.

By comparing FIG. 11 with FIG. 12, it can be found that the capacity ofa Fresnel zone plate with a facet of 30 cm′30 cm for exciting a opticalgain medium 4 (i.e. Er-doped glass) is no smaller than that of a 980 nmpump laser of 100 mW. In addition, when the sunlight is focused onto theoptical gain medium 4 (i.e. Er-doped glass), because the light beam iswider than the optical gain medium 4 (i.e. Er-doped glass), not all ofthe energy is propagated into it. In the other hand, the 980 nm pumplaser is propagated through the fiber so that a strong power can befocused and propagated in a smaller area to obtaining a higher excitedstate population inversion in optical gain medium 4 (i.e. Er-dopedglass).

Therefore, by way of focusing the sunlight, the efficiency of theexciting by a high-power 980 nm pump laser can be easily achieved.Therefore, if the solar optical amplifier is widely used, it would carryout a great technique revolution in the field of the opticalcommunications, especially in satellite optical communications andground wireless optical communications.

The preferred embodiments herein disclosed are not intended tounnecessarily limit the scope of the invention. Therefore, simplemodifications or variations belonging to the equivalent of the scope ofthe claims and the instructions disclosed herein for a patent are allwithin the scope of the present invention.

1. A solar-pumped active device, comprising: a substrate; an opticaldiffraction element; a first optical reflection element; an optical gainmedium; an optical waveguide; an input port; an output port; ananti-reflection film; and a reflection layer, wherein said substrate iscovered with said reflection layer and on said substrate are said firstoptical reflection element, said optical waveguide and saidanti-reflection film; wherein a required wavelength in sunlight iscoupled by said optical diffraction element on said substrate and saidfirst optical reflection element in said optical waveguide and then saidwavelength is converged to said optical gain medium; and wherein,accordingly, an amplifier is obtained by amplifying the input signalsfrom said input port and outputting said input signals by said outputport.
 2. The device according to claim 1, wherein said opticaldiffraction element is a holographic antenna grating.
 3. The deviceaccording to claim 1, wherein said optical diffraction element is aphotonic crystal.
 4. The device according to claim 1, wherein said firstoptical reflection element is a Bragg grating.
 5. The device accordingto claim 1, wherein said first optical reflection element is a photoniccrystal.
 6. The device according to claim 1, wherein said opticaldiffraction element is to be a waveguide layer.
 7. The device accordingto claim 6, wherein said waveguide layer is a silicon dioxide.
 8. Thedevice according to claim 6, wherein said waveguide layer is a polymer.9. The device according to claim 1, wherein said optical diffractionelement is a grating in a surface-relief type.
 10. The device accordingto claim 1, wherein said optical diffraction element is a grating in anindex-modulation type.
 11. The device according to claim 1, wherein thematerial of said substrate is selected from the group consisting of asolar energy silicon substrate, a metal, a polymer, a semiconductormaterial, and a dielectric material.
 12. The device according to claim2, wherein the shape of said holographic antenna grating is selectedfrom the group consisting of a circle and an ellipse.
 13. The deviceaccording to claim 2, wherein the shape of said holographic antennagrating is a geometric shape.
 14. The device according to claim 1,wherein said optical gain medium is an erbium-doped (Er-doped) glass.15. The device according to claim 14, wherein said Er-doped glass isradiation-hardened.
 16. The device according to claim 14, wherein saidEr-doped glass is further aluminum-doped (Al-doped).
 17. The deviceaccording to claim 1, wherein said optical gain medium is anytterbium-doped (Yb-doped) material.
 18. The device according to claim17, wherein said Yb-doped material is further Al-doped.
 19. The deviceaccording to claim 1, wherein said optical gain medium is doped with arare earth element.
 20. The device according to claim 19, wherein saidoptical gain medium is further boron-doped (B-doped).
 21. The deviceaccording to claim 19, wherein said optical gain medium is furthergermanium-doped (Ge-doped).
 22. The device according to claim 1, whereinsaid optical gain medium is doped with Erbium and Ytterbium(Er/Yb-doped).
 23. The device according to claim 22, wherein saidoptical gain medium is further B-doped.
 24. The device according toclaim 22, wherein said optical gain medium is further Ge-doped.
 25. Thedevice according to claim 1, wherein said optical gain medium isselected from the group consisting of an Er-doped glass and anEr/Yb-doped glass; wherein said optical gain medium is B-doped; andwherein said optical diffraction element is a holographic grating layerdoped with fluorine (F-doped).
 26. The device according to claim 1,wherein the material dispersion slope of said optical gain medium ishigher than that of said optical diffraction element.
 27. The deviceaccording to claim 1, wherein the host material of said optical gainmedium is selected from the group consisting of a phosphate glass, afluorophosphates glass, a silicate glass, and a borate glass.
 28. Thedevice according to claim 1, wherein said optical diffraction element isto diffract a pump light.
 29. The device according to claim 1, whereinsaid first optical reflection element is a reflection grating for pumpwavelength.
 30. A solar-pumped active device, comprising: a substrate;an optical diffraction element; a first optical reflection element; asecond optical reflection element; an optical waveguide; an optical gainmedium; an output port; an anti-reflection film; and a reflection layer,wherein said substrate is covered with said reflection layer and on saidsubstrate are said first optical reflection element, said opticalwaveguide, said optical gain medium and said anti-reflection film;wherein the required wavelength in sunlight is coupled by said opticaldiffraction element on said substrate and said first optical reflectionelement in said optical waveguide and then said wavelength is convergedto said optical gain medium; and wherein, accordingly, a laser isobtained in coordination with said second optical reflection element andis outputted by said output port.
 31. The device according to claim 30,wherein said optical diffraction element is a holographic antennagrating.
 32. The device according to claim 30, wherein said opticaldiffraction element is a photonic crystal.
 33. The device according toclaim 30, wherein said first optical reflection element is a Bragggrating.
 34. The device according to claim 30, wherein said firstoptical reflection element is a photonic crystal.
 35. The deviceaccording to claim 30, wherein said second optical reflection element isa laser reflection grating.
 36. The device according to claim 30,wherein said second optical reflection element is a photonic crystal.37. The device according to claim 30, wherein said optical diffractionelement is to be a waveguide layer.
 38. The device according to claim37, wherein said waveguide layer is a silicon dioxide.
 39. The deviceaccording to claim 37, wherein said waveguide layer is a polymer. 40.The device according to claim 30, wherein said optical diffractionelement is a grating in a surface-relief type.
 41. The device accordingto claim 30, wherein said optical diffraction element is a grating in anindex-modulation type.
 42. The device according to claim 30, wherein thematerial of said substrate is selected from the group consisting of asolar energy silicon substrate, a metal, a polymer, a semi-conductormaterial and a dielectric material.
 43. The device according to claim31, wherein the shape of said holographic antenna grating is selectedfrom the group consisting of a circle and an ellipse.
 44. The deviceaccording to claim 31, wherein the shape of said holographic antennagrating is a geometric shape.
 45. The device according to claim 30,wherein said optical gain medium is an Er-doped glass.
 46. The deviceaccording to claim 45, wherein said Er-doped glass isradiation-hardened.
 47. The device according to claim 45, wherein saidEr-doped glass is further Al-doped.
 48. The device according to claim30, wherein said optical gain medium is an Yb-doped material.
 49. Thedevice according to claim 48, wherein said Yb-doped material is furtherAl-doped.
 50. The device according to claim 30, wherein said opticalgain medium is doped with a rare earth element.
 51. The device accordingto claim 50, wherein said optical gain medium is further B-doped. 52.The device according to claim 50, wherein said optical gain medium isfurther Ge-doped.
 53. The device according to claim 30, wherein saidoptical gain medium is Er/Yb co-doped.
 54. The device according to claim53, wherein said optical gain medium is further B-doped.
 55. The deviceaccording to claim 53, wherein said optical gain medium is furtherGe-doped.
 56. The device according to claim 30, wherein said opticalgain medium is selected from the group consisting of an Er-doped glassand an Er/Yb-doped material; wherein said optical gain medium isB-doped; and wherein said optical diffraction element is an F-dopedholographic grating layer.
 57. The device according to claim 30, whereinthe material dispersion slope of said optical gain medium is higher thanthat of said optical diffraction element.
 58. The device according toclaim 30, wherein the host material of said optical gain medium isselected from the group consisting of a phosphate glass, afluorophosphates glass, a silicate glass and a borate glass.
 59. Thedevice according to claim 30, wherein said optical diffraction elementis to diffract a pump light.
 60. The device according to claim 30,wherein said first optical reflection element is a reflection gratingfor pump wavelength.
 61. A solar-pumped active device, comprising: asubstrate; an optical diffraction element; a first optical reflectionelement; an optical gain medium; an optical waveguide; an input port; anoutput port; an anti-reflection film; and a reflection layer, wherein anamplifier is obtained by a serial connection as connecting the outputport of one said solar-pumped active device and the input port ofanother said solar-pumped active device.
 62. The device according toclaim 61, wherein said optical diffraction element is a holographicantenna grating.
 63. The device according to claim 61, wherein saidoptical diffraction element is a photonic crystal.
 64. The deviceaccording to claim 61, wherein said first optical reflection element isa Bragg grating.
 65. The device according to claim 61, wherein saidfirst optical reflection element is a photonic crystal.
 66. Asolar-pumped active device, comprising: a substrate; an opticaldiffraction element; a first optical reflection element; an optical gainmedium; an optical waveguide; an input port; an output port; ananti-reflection film; and a reflection layer, wherein an amplifier isobtained by a serial connection as connecting the output port of onesaid solar-pumped active device and the input port of another saidsolar-pumped active device.
 67. The device according to claim 66,wherein said optical diffraction element is a holographic antennagrating.
 68. The device according to claim 66, wherein said opticaldiffraction element is a photonic crystal.
 69. The device according toclaim 66, wherein said first optical reflection element is a Bragggrating.
 70. The device according to claim 66, wherein said firstoptical reflection element is a photonic crystal.
 71. The deviceaccording to claim 66, wherein said second optical reflection element isa laser reflection grating.
 72. The device according to claim 66,wherein said second optical reflection element is a photonic crystal.